This can be done in `O(n)`

time and `O(1)`

space.

(The algorithm only works because the numbers are consecutive integers in a known range):

In a single pass through the vector, compute the sum of all the numbers, and the sum of the squares of all the numbers.

Subtract the sum of all the numbers from `N(N-1)/2`

. Call this `A`

.

Subtract the sum of the squares from `N(N-1)(2N-1)/6`

. Divide this by `A`

. Call the result `B`

.

The number which was removed is `(B + A)/2`

and the number it was replaced with is `(B - A)/2`

.

## Example:

The vector is `[0, 1, 1, 2, 3, 5]`

:

N = 6

Sum of the vector is 0 + 1 + 1 + 2 + 3 + 5 = 12. N(N-1)/2 is 15. A = 3.

Sum of the squares is 0 + 1 + 1 + 4 + 9 + 25 = 40. N(N-1)(2N-1)/6 is 55. B = (55 - 40)/A = 5.

The number which was removed is (5 + 3) / 2 = 4.

The number it was replaced by is (5 - 3) / 2 = 1.

## Why it works:

The sum of the original vector `[0, ..., N-1]`

is `N(N-1)/2`

. Suppose the value `a`

was removed and replaced by `b`

. Now the sum of the modified vector will be `N(N-1)/2 + b - a`

. If we subtract the sum of the modified vector from `N(N-1)/2`

we get `a - b`

. So `A = a - b`

.

Similarly, the sum of the squares of the original vector is `N(N-1)(2N-1)/6`

. The sum of the squares of the modified vector is `N(N-1)(2N-1)/6 + b`^{2} - a^{2}

. Subtracting the sum of the squares of the modified vector from the original sum gives `a`^{2} - b^{2}

, which is the same as `(a+b)(a-b)`

. So if we divide it by `a - b`

(i.e., `A`

), we get `B = a + b`

.

Now `B + A = a + b + a - b = 2a`

and `B - A = a + b - (a - b) = 2b`

.